FR2972097A1 - Method for assigning e.g. mobile station to voice mail server for managing voicemail subscribers of voice network, involves obtaining geological information and assigning terminal based on information - Google Patents

Abstract

The method involves obtaining geological information associated to a mobile terminal i.e. mobile station or radio terminal, and indicating a geographical area where the mobile terminal is frequently provided for a determined time duration. The mobile terminal is assigned to a voice mail server (SVA) that is selected from a number of voicemail servers based on geological information associated with the mobile terminal. Each voicemail server is connected to a set of central switching nodes (A-D). Independent claims are also included for the following: (1) a method for routing a voicemail call (2) a device for assigning a mobile terminal to a voice mail server (3) a device for routing a voicemail call.

Description

A method of assigning a mobile terminal to a voicemail server, and corresponding method of routing a voicemail call issued by a mobile terminal. FIELD OF THE INVENTION The field of the invention is that of voice messaging systems, managing the voice messages of the subscribers of a telecommunications network. A voicemail system consists of one or more servers called voicemail servers (or voice servers) hosting mailboxes (each subscriber is a voicemail box). In the context of the present invention, we are interested in the case of a voicemail for mobile subscribers, that is to say for subscribers with mobile terminals (also called "mobile stations" or "radiocommunication terminals") . More specifically, the invention relates to a technique for managing the manner in which mobile terminals are distributed among a plurality of voicemail servers, as well as the manner in which calls from these mobile terminals are routed to the voicemail servers.

BACKGROUND OF THE INVENTION A voicemail system makes it possible, in particular, to deposit, notify and consult voice messages. Consider a mobile subscriber X whose mailbox is hosted by an SVX voice server. Suppose that a subscriber Y (fixed or mobile, belonging or not to the same network as the subscriber X) sends a voice call to the subscriber X. In a certain number of cases, the voice call is not established between subscribers X and Y, especially if the mobile of subscriber X is off or out of network coverage, or if subscriber X does not answer the call or refuses it. The call is automatically forwarded to the SVX voice server. Once the call established between the subscriber Y and the voice server SVX, the subscriber Y hears the voice announcement of the subscriber X (announcement predefined by the subscriber X, generally inviting callers to leave a message, and played by the SVX voice server). The subscriber Y then has the possibility of recording a voice message in the mailbox of X. At the end of this recording, the voice server SVX notifies the subscriber X of the repository of this new voice message, generally by sending him an SMS message. Thus informed of the presence of a new voice message in his voice mailbox, the subscriber X can make a voice call to the voicemail (in this case to the voice server SVX) to listen to his voice message. A short number corresponding to voicemail (for example the "888" at France Telecom - Orange) is generally set up in the network to simplify this consultation call. The voicemail consultation generates a significant daily traffic impacting the dimensioning of the switched network, and especially during the annual traffic peaks ("New Year" type). At a time when the ambition of telecommunication networks is to be more economical in terms of resources and energy consumed, the optimization of the voicemail service - a basic service used by everyone every day - is of paramount importance. A call to voicemail is a "voice" call that is inherently based on circuit switching. This type of switching mobilizes end-to-end the bidirectional voice channel used throughout the duration of the call, and this exclusively. Currently the voice mail servers divide the treatment of mobile subscribers (that is to say the management of the mailboxes of these mobile subscribers) according to an arbitrary and static division determined by the operator (typically, by increments of numbers d subscribers).

A disadvantage of this current solution is that it does not allow any topological optimization of the switching nodes traversed during the establishment of the circuits. In particular, there is no optimization of the number of switching nodes traversed during the establishment of the circuits. It is recalled that for each call of a mobile terminal to its voicemail server, a circuit is open between these two entities, which passes through switching nodes.

3. DISCLOSURE OF THE INVENTION In a particular embodiment of the invention, there is provided a method of assigning a mobile terminal to a voice mail server, comprising the following steps: obtaining information geolocation associated with the mobile terminal, indicating a geographic area where the mobile terminal is most frequently over a given time period; - Assigning the mobile terminal to a voicemail server selected from a plurality of voicemail servers based on the geolocation information associated with the mobile terminal. The general principle of the invention is therefore, for the distribution (that is to say the assignment) of mobile terminals among the voicemail servers, to replace the distribution by subscriber number slots (to each server voicemail are assigned to mobile terminals whose subscriber numbers are included in a predefined slice of subscriber numbers), by a distribution taking into account geolocation information associated with the mobile terminals (location is taken into account). where is most frequently each mobile terminal). Thus, it is possible to implement an optimal routing policy (see the "first routing policy" detailed hereinafter), based on the bet that there is a high probability that a mobile terminal, when it issues a voicemail call, is in its usual geographical area (that is, in the area where it is most frequently located over a specified time period), and therefore that routing can be done from to the right voicemail server (that is to say the one to which the mobile terminal has been previously allocated), thus realizing an optimization of the number of switching nodes traversed during the establishment of a circuit between the mobile terminal and its voicemail server. According to a particular embodiment of the invention, each of the voice mail servers is connected to a switching node, and the geolocation information associated with the mobile terminal indicates the most frequent switching node for the mobile terminal, defined as the switching node traversed most frequently, during calls made during said time period determined by the mobile terminal, among the switching nodes to each of which is connected one of the voice mail servers, In addition, the step of Assignment is to assign the mobile terminal to the voicemail server connected to the most common switching node for the mobile terminal.

The information that constitutes "the most common switching node for the mobile terminal") is a geolocation information that is easy to obtain because it is already present in call tickets. This particular implementation of the assignment method is easy to achieve and inexpensive.

According to a particular characteristic, the obtaining step is reiterated at least once and, if new geolocation information is obtained for the given mobile terminal, the assignment step is reiterated and comprises a mobile terminal migration step. to another voicemail server selected based on the new geolocation information.

Thus, the assignment of a mobile terminal to a voicemail server is not fixed but can be changed dynamically, thus always having the optimal allocation to implement the associated routing policy. According to a particular characteristic, the switching nodes belong to a hierarchical network comprising a mesh of at least two central switching nodes, and each voicemail server is connected to one of the central switching nodes. In this way, we limit the risks of congestion in case of high attendance on the voicemail servers. In another particular embodiment of the invention, there is provided a method of routing a voicemail call transmitted by a mobile terminal, a first switching node implementing the following steps: obtaining a geolocation information associated with the mobile terminal, indicating a geographical area where the mobile terminal is most frequently located over a given time period; and establishing a circuit for routing the call to a voicemail server selected from a plurality of voicemail servers based on the location information associated with the mobile terminal. This routing method is intimately related to the implementation of the aforementioned assignment method since the call is routed to a selected mail server as in the assignment method, that is to say selected as a function of geolocation information, associated with the mobile terminal, indicating a geographical area where the mobile terminal is most frequently on a determined temporal duration. According to one embodiment, the first switching node implements, when the mobile terminal is attached to a base station connected to the first switching node, a first routing policy comprising the following steps: an attempt to route the call to a default voicemail server for the first switch node, and, - if a negative acknowledgment is received indicating that the mobile terminal has not been previously assigned to the default voicemail server, execution steps of obtaining and establishing. This first routing policy is intimately linked to the implementation of the aforementioned assignment method, and consists in first attempting to route the voicemail call to the default voicemail server, before routing the call. to a mail server determined according to the geolocation information. According to one embodiment, the default voicemail server is associated with a predetermined geographical area such that, when a given mobile terminal is there most frequently over a given time period, the given mobile terminal is assigned to this voicemail server by default. By first attempting to route the voicemail call to the default voicemail server for the geographic area in which the mobile terminal is currently located, it is indeed the bet that the mobile terminal is at the same time. this moment in his usual geographical area, and therefore the default voicemail server is indeed his voicemail server (that is to say, the one to which it was assigned). If so, the circuitry between the mobile terminal and its voicemail server is established quickly and with a minimum number of traversed switching nodes. This optimizes the routing of the call. Otherwise, the first switch node must look for a secondary route (between the mobile terminal and its voicemail server), which it does by obtaining the geolocation information associated with the mobile terminal. This first routing policy is adapted to low migration geographical areas, that is to say geographical areas (for example residential areas) where there is a high probability (more than 50% for example) that the terminals mobile phones in their usual geographical area. According to one particular feature, the predetermined geographic area associated with the default voicemail server for the first switch node is a geographical area covered by a set of base stations that are operatively connected to a set of switch nodes, to which the base station belongs. first switching node and comprising switching nodes hierarchically dependent on the switching node to which is connected the default voicemail server. Thus, one simply defines the predetermined geographical area associated with the default voicemail server for the first switching node. According to a particular characteristic, the first switching node implements a second routing policy when the mobile terminal is attached to a base station connected to the first switching node, performing the steps of obtaining and setting up, without attempt prior to routing the call to a default voice mail server for the first switch node. This second routing policy is adapted to high-migration geographical areas, ie to geographical areas (for example areas covering highways) where there is a low probability (less than 50% for example) that mobile terminals are in their usual geographical area (high probability of 20 homeless people). Indeed, in this case, the application of the first routing policy would be counterproductive. The second routing policy differs from the first in that it starts directly by obtaining the geolocation information associated with the mobile terminal. This makes it possible not to unnecessarily solicit the default voicemail server of the zone (it is wagered that there is no reason a priori for this default mail server to be the voicemail server to which has been assigned the mobile terminal), and thus reduce the time of establishment of the circuit between the mobile terminal and its voicemail server. Thus, two separate routing policies are available, and it can be decided in a predetermined manner which one to apply in each switching node. As indicated below, in an alternative embodiment, it is possible to dynamically modify this choice, as a function of at least one predetermined criterion. For example, the switching nodes corresponding to a given geographical area apply the first routing policy during periods of the low-traffic year on the routes of this zone, and the second routing policy during periods of the year of the year. high traffic on the roads of this area. According to one particular embodiment of the invention, each of the voice mail servers is connected to a switching node, and the geolocation information associated with the mobile terminal indicates the most frequent switching node for the mobile terminal, defined as the most frequently traversed switching node, during calls made during said time period determined by the mobile terminal, among the switching nodes to each of which is connected one of the voicemail servers. In addition, the step of setting up a circuit consists in establishing a circuit to the voicemail server connected to the most frequent switching node for the mobile terminal. The information that constitutes "the most common switching node for the mobile terminal") is a geolocation information that is easy to obtain because it is already present in call tickets. This particular implementation of the routing method is easy to achieve and inexpensive. According to one particular characteristic, the routing method comprises a step of dynamically changing the routing policy associated with the first switching node, with passing from the first to the second routing policy or vice versa, as a function of at least one predetermined criterion. . Thus, one can adapt the choice of the routing policy applied by a switching node. In another embodiment of the invention there is provided a computer program product which comprises program code instructions for implementing the aforementioned assignment method and / or the aforementioned routing method (each in any of its various embodiments), when said program is run on a computer. In another embodiment of the invention, there is provided a computer-readable and non-transitory storage medium, storing a computer program comprising a set of instructions executable by a computer to implement the assignment method. aforementioned and / or the aforementioned routing method (each in any one of its various embodiments). The invention also relates to a device for assigning a mobile terminal to a voicemail server, comprising: means for obtaining geolocation information associated with the mobile terminal, indicating a geographical area where the most frequently the mobile terminal over a determined time period; means for assigning the mobile terminal to a voicemail server selected from a plurality of voicemail servers according to the geolocation information associated with the mobile terminal. The advantages stated above for the assignment method can be directly transposed to this assignment device. The invention also relates to a device for routing a voicemail call transmitted by a mobile terminal, comprising: means for obtaining geolocation information associated with said mobile terminal, indicating a geographical area where the most frequently the mobile terminal over a determined time period; and circuit establishment means for routing the call to a voicemail server selected from a plurality of voicemail servers based on the geolocation information associated with the mobile terminal. The advantages stated above for the routing method can be directly transposed to this routing device.

4. LIST OF FIGURES Other characteristics and advantages of the invention will appear on reading the following description, given by way of indicative and nonlimiting example, and the appended drawings, in which: FIG. 1 presents a block diagram; a system according to a particular embodiment of the invention; FIG. 2 presents a flowchart of a particular embodiment of the assignment method according to the invention; FIG. 3 presents a flowchart of a particular embodiment of the routing method of the invention, according to a first routing policy; FIG. 4 presents a flowchart of a particular embodiment of the routing method of the invention, according to a second routing policy; FIG. 5 shows the structure of an assignment device according to a particular embodiment of the invention; and FIG. 6 shows the structure of a switching node according to one particular embodiment of the invention. 5. DETAILED DESCRIPTION We now present, in connection with Figure 1, a system according to a particular embodiment of the invention. The system comprises in particular: a communication network (voice network) built according to an arbitrary topology comprising a plurality of switching nodes (for example, but this is not mandatory, a hierarchical topology, as detailed later); a plurality of base stations each connected to one of the switching nodes. For the sake of simplification, only some base stations are shown in Figure 1, which are referenced S1, S2 and S3; a plurality of mobile terminals, each at the disposal of a mobile subscriber. At a time t, each mobile terminal is attached to a mobile station (that is to say it accesses the mobile network and communicates via this mobile station). For the sake of simplification, only certain mobile terminals are shown in Figure 1, which are referenced Xl, X2 and X3, and whose subscriber numbers (MSISDN) are respectively 068081xyzl, 068081xyz2 and 068081xyz3. It is assumed in this example that at a time t, the mobile terminals X1, X2 and X3 are attached to the base stations S1, S2 and S3 respectively; A plurality of voicemail servers. In the example of Figure 1, there are four (referenced SVA, SVB, SVC and SVD), each connected to one of the switching nodes. In the example of Figure 1, the voice network is a hierarchical network consisting of a mesh of several central switching nodes (referenced A, B, C and D), and which themselves constitute a "star" for secondary switching nodes (for example referenced A1, A2 and A3 for those which depend hierarchically on the node A, and C1, C2 and C3 for those which depend on the node C), which themselves may constitute the center of a star of smaller nodes (for example Al 1 and Al 2 refer to those which depend hierarchically on node A1, A31, A32 and A33 for those which depend on node A3, C31, C32 and C33 for those which are hierarchically dependent on node C3), and thus right now. In the example of FIG. 1, each voicemail server (SVA, SVB, SVC or SVD) is connected to (i.e., located under, in this hierarchical context) one of the central switching nodes (A , B, C and D). This limits a priori the risk of congesting the voice channels of a secondary beam in case of high attendance on the voicemail server. It is clear, however, that in the context of the present invention, the node to which a voice mail server is connected is not necessarily a central switching node. Indeed, the topology distributing mail servers is likely to vary from one operator network to another. The subarray RA consists of the switching nodes hierarchically located under the node A (in the example of FIG. 1, the subarray RA comprises the nodes referenced A1, A1 1, Al2, A2, A3, A31, A32 and A33). It also considers all the base stations SA which are functionally connected to the switching nodes of the subarray RA (the base stations referenced S1 and S2 belong to this set SA): each of these base stations is configured to communicate with at least one of the switching nodes of the sub-network RA and serves as a communication medium with respect to the sub-network RA for any terminal attached to this station. This set of base stations SA covers a homogeneous geographical area: it is assumed here that the sub-network RA corresponds geographically to a continuous topological surface. In a particular embodiment of the invention, a geolocation mechanism of mobile terminals is used over the water, on a sliding observation window (from a few days to a few months for example). The geolocation data, changing over time, are aggregated in the form of simple geolocation information, indicating for each mobile terminal the first central switching node crossed most frequently when the mobile terminal makes a call (to its messaging voice, or to any correspondent, this without loss of generality of the invention).

Such geolocation information ("most common central switching node" for each mobile terminal) is simple to obtain a priori, because it is already present in the detail of call tickets (CDR). The amount of information collected is therefore easily available, and it is much less voluminous than all the theoretically available geolocation information, namely all the base stations on which the mobile terminal has "successively" attached during the subscriber movements, including out of communication. The above example of geolocation information is a practical choice of implementation, this without loss of generality of the invention compared to other more granular geolocation information.

This mechanism produces, for example, a simple table of the following form: MSISDN (mobile subscriber number) Central node 068081xyzl A 068081xyz2 A 068081xyz3 A 068081xyz4 B etc. etc.

Only the nodes behind each of which is actually hosted (ie each of which is connected) are listed in the right-hand column. Once this table has reached a state deemed stable, an initial distribution of the mobile terminals among the voicemail servers is carried out, applying the following rule: each mobile terminal is assigned to the voicemail server which is connected to the "node of "most common central switching" for this mobile terminal, according to the table. We therefore abandon the traditional technique of distribution according to an arbitrary and static division (determined by the operator), by subscriber number slots (see discussion above). In a particular embodiment, this distribution then changes over time as a function of the update of the table (that is to say for example according to the size of the sliding observation window used in the geolocation mechanism of mobile terminals along the water).

In this case, for example, an ordinary mechanism for transferring voicemail from one voicemail server to another is used. This feature has existed for many years in industrial products. Indeed, the main voice mail providers offer voice mailbox migration tools. These migration tools are mainly used by operators when they add one or more voice servers in their network (to support the increase in their number of subscribers for example): operators can offload existing voice servers by moving some mailboxes that they hosted to the voice servers that have just been put into service. These migration tools are used to move a set of mailboxes (with all their content: greeting, voice messages, usage settings, etc.) from a first voice server to a second voice server. Boxes are usually migrated by number ranges. Finally, it should be noted that these migration tools generally ensure the continuity of the voice mail service during a migration operation (the repository, and possibly the consultation of messages remaining possible during the migration of a mailbox).

FIG. 2 presents a flowchart of this particular embodiment of the assignment method according to the invention. In a step 21, for each mobile terminal, one obtains geolocation information ("most common central switching node" for this mobile terminal) indicating a geographical area where the mobile terminal is most frequently over a given time period. This information is stored in the aforementioned table. It is recalled that "the most frequent switching node" for the mobile terminal is defined as the switching node most frequently traversed, during calls made during a time period determined by the mobile terminal, from the switching nodes to each one. of which is connected one of the voicemail servers. In a step 22, each mobile terminal is assigned to the voicemail server which is connected to the "most frequent central switching node" of this mobile terminal. In a step 23, it is reiterated obtaining, for each mobile terminal, its geolocation information (step c 21 detailed above).

In a step 24, for each mobile terminal, it is checked whether the geolocation information has changed. If no geolocation information has changed, we return directly to step 23. If the location information has changed for at least one of the mobile terminals, we go to step 25 in which, we reassign each mobile terminal according to its new location information (new "most common central switching node"). For each reassigned mobile terminal, it is migrated from its old voicemail server to a new voicemail server (that is, the one linked to the new "most frequent central switching node" of this reassigned mobile terminal. ).

FIG. 5 shows the simplified structure of an assignment device implementing the assignment method according to the invention (for example the particular embodiment described above in relation to FIG. 2). This allocation device comprises a RAM 53, a processing unit 51, equipped for example with a processor and controlled by a computer program stored in a ROM 52. At initialization, the code instructions of the program For example, a computer is loaded into the RAM 53 before being executed by the processor of the processing unit 51. The processing unit 51 receives, for example, the details of the call tickets (CDR) 50 as input. mobile terminals. The processor of the processing unit 51 generates, for example, migration instructions 54 as a function of the content of the aforementioned table 54 (associating a "most common central switching node" with each mobile terminal). This FIG. 5 only illustrates one particular way, among several possible, to produce the algorithm detailed above, in relation with FIG. 2. Indeed, the assignment technique of the invention is carried out indifferently: on a machine of reprogrammable calculation (PC computer, DSP processor or microcontroller) executing a program comprising a sequence of instructions; or on a dedicated computing machine, that is to say in the form of hardware (for example a set of logic gates such as an FPGA ("Field Programmable Gate Array" in English) or an ASIC ("Application-Specific Integrated Circuit") In English), or any other hardware module). In the case where the invention is implemented on a reprogrammable calculation machine, the corresponding program (that is to say the instruction sequence) can be stored in a removable storage medium (such as for example a diskette, a CD-ROM or a DVD-ROM) or not, this storage medium being readable partially or totally by a computer or a processor. This distribution (initial or update) of mobile terminals among the voicemail servers) is supposed to be established, the following details the mechanism for routing a call sent by a mobile terminal to the voicemail. We now present, in connection with Figure 3, a first routing policy, corresponding to the cases of low migration geographical areas. By way of example, the mobile terminals X 1 and X 3 are considered, each having the "most common central switching node" as the node A, behind which is located (to which is connected) the voicemail server SVA. Given the above (see above the presentation of the assignment method according to the invention), the voicemail server SVA hypothetically hosts the mailbox of each of the mobile terminals X1 and X3. It is assumed that, at a time t, each mobile terminal X1 or X3 is located geographically at an arbitrary point of the network and the following details the routing mechanism implemented in the first switching node to which the base station is functionally connected to. which is attached to the mobile terminal.

Two cases can arise, depending on whether the mobile terminal Xl or X3 is located in the geographical zone characterized by all the base stations SA (in other words, depending on whether the first switching node mentioned above is functionally connected to the base station to which the mobile terminal is attached, belongs to the RA subnet or not). Recall that the subarray RA consists of the switching nodes hierarchically located under the node A (in the example of FIG. 1, the subarray RA comprises the nodes referenced Al, Al 1, Al2, A2, A3, A31, A32 and A33). It is also recalled that the set SA is the set of base stations which are functionally connected to the switching nodes of the subarray RA (the base stations referenced S1 and S2 belong to this set SA). This set of base stations SA covers a homogeneous geographical area. In the example of FIG. 1, it is assumed that at time t: the mobile terminal X1 is in the geographical zone characterized by the set of base stations SA, since the mobile terminal X1 is attached to the base station S1 which is operatively connected to switching node Al2 (first switching node for mobile terminal X1) which belongs to subarray RA; and the mobile terminal X3 is not located in the geographical area characterized by all the base stations SA, since the mobile terminal X3 is attached to the base station S3 which is functionally connected to the switching node C33 (first node). for the mobile terminal X3) that does not belong to the subnet RA (it belongs to the subnet RC). However, each "first switching node" must have a nominal behavior by default, since it does not know when it receives a voicemail call from a mobile terminal, if this mobile terminal has previously been assigned to the mail server the central switching node of which this "first switching node" depends. In other words, this "first switching node" does not know if the voicemail server associated with the subnet to which it belongs is the voicemail server to which this mobile terminal has been assigned. Indeed, this information is strictly unknown to the routing tables of this "first switching node".

The default nominal behavior of the "first switching node" (step 31) is to attempt routing to the voicemail server located behind the central switching node of which this "first switch node" depends (which is an attempt to static routing by essence). In the rest of the description, this voicemail server is called "default voicemail server" for the "first switching node". The bet made by the "first switching node" is that there is a high probability that the mobile terminal is in its usual geographical area and that the routing is done from the outset to the right voicemail server.

If the mobile terminal is indeed in its usual geographical area (high probability) (positive test response of step 32), the default voicemail server recognizes the mobile number as part of the messaging accounts under its responsibility, and it processes the call (a circuit is established between the mobile terminal and the default voicemail server). Then, the "first switching node" goes to the end step referenced 33. In the example of FIG. 1, this is the case for the mobile terminal X1: the switching node Al2 (first switching node for the mobile terminal Xl) attempts routing to the SVA voicemail server that processes the call since it is in charge of the mailbox of the mobile terminal Xl.

If the mobile terminal is not in its usual geographical area (low probability) (negative answer to the test in step 32), the default voicemail server, which does not manage this mobile terminal, performs a negative acknowledgment. On receipt of this negative acknowledgment, the "first switching node" must therefore look for a secondary route. A new function is introduced on the cellular network, which indicates (for example in client-server mode) the voicemail server corresponding to a mobile number provided as input. This function is in fact the consultation of the table constituted above (containing the geolocation information). By analogy with the existing terminology of "HLR" ("Home Location Register"), this new functional brick is for example named "BLR" for ("Box Location Register"). It is also possible that this function of BLR is in practice carried by an equipment type HLR. The "first switching node" simply queries the equipment implementing the BLR function (step 34), to know the voicemail server on which the mobile terminal depends. Upon receipt of the response, the "first switching node" establishes a circuit to that voice mail server (step 35), via the corresponding central switching node ("most common central switching node") contained in the table and provided in the answer). Then, the "first switching node" goes to the end step referenced 36. In the example of FIG. 1, this is the case for the mobile terminal X3: the switching node C33 (first switching node for the mobile terminal X3) attempts routing to the SVC voicemail server which does not process the call and makes a negative acknowledgment since it is not in charge of the mailbox of the mobile terminal X3. The switching node C33 interrogates the equipment implementing the function of BLR, to know the voicemail server on which the mobile terminal X3 depends. Upon receipt of the response (ie the SVA voicemail server), the switching node C33 establishes a circuit to this voice mail server SVA via the central switching node A ("most common central switching node" provided). in the answer). A second routing policy is now presented, in connection with FIG. 4, corresponding to the cases of high migration geographical zones.

The first routing policy systematically produces a gain in terms of the economy of central nodes traversed for the establishment of a circuit, but it can become counterproductive in the particular case of geographical areas of high migration covers (for example, areas covering motorways). The probabilities set out above are intended to be reversed (almost all homeless people).

The second routing policy therefore provides that for such high migration areas, the routing performed by the "first switching node" for the mobile terminal begins directly with the request to the equipment implementing the function of BLR. In other words, the step of attempting to route to the voicemail server of the area (i.e., the one behind the central switching node of which this "first switch node" depends) is removed. . The benefits are: no unnecessary solicitation of the voicemail server in the zone, and faster setup time (between the mobile terminal and its voicemail server). The second routing policy therefore comprises steps 41 and 42 identical to steps 34 and 35 of FIG.

The threshold delimiting the routing policy (among the first and second policies described above) to be adopted by each "first switching node" can be adjusted taking into account different criteria, this without loss of generality for the present invention. However, the natural threshold is 50%: the first routing policy for a geographical area is chosen if the probability P that the mobile terminals therein are in their usual geographical area is such that P is greater than or equal to 50 %. The second routing policy is chosen in the case where P is less than 50%. The routing policy to be adopted by a "first switching node" can also be dynamically modified on the basis of seasonal criteria (periods of high traffic on the roads).

Updates in the table (database) managed by the equipment implementing the BLR feature, result in mailbox migrations from an old voicemail server to a new voicemail server, for each mobile terminal. These migrations can be carried out in several ways, without loss of generality for the present invention - and among others: - according to an event principle: when a table entry changes, a voice mailbox migration order (from the old the new voicemail server) is sent to the old voicemail server, by the equipment implementing the function of BLR; - according to a principle of recurrent updating (for example every month), and whose triggering criterion can have an automatic character or performed by a technician (all subscriptions that have been modified since the last update are migrated at the same time ). In any case, it is preferable that the migration process, which is critical, is strictly transactional, and allows backtracking and backups.

In the management of the table (which collects geolocation information), it is possible to introduce a mechanism for replacing the mobile numbers (which are sensitive data) with a substitution value (mechanism of unidirectional aliasing on the numbers of mobile). For example, we use a public key / private key encryption algorithm whose private key has been "destroyed" (it is possible to encode but not to decode). FIG. 6 shows the simplified structure of a switching node implementing the routing method according to the invention (either according to the first routing policy described above in connection with FIG. 3, or according to the second routing policy described above in connection with FIG. 4), when it behaves like the "first switching node" to which the base station to which the mobile terminal is attached is functionally connected. This switching node comprises a RAM 63, a processing unit 61, equipped, for example, with a processor and controlled by a computer program stored in a ROM 62. At initialization, the code instructions of the program are, for example, loaded into the RAM 63 before being executed by the processor of the processing unit 61. This FIG. 6 only illustrates one of several possible ways of carrying out the algorithms detailed above, relationship with FIGS. 3 and 4. Indeed, the routing technique of the invention is carried out indifferently: on a reprogrammable calculation machine (PC computer, DSP processor or microcontroller) executing a program comprising a sequence of instructions; or on a dedicated computing machine, that is to say in the form of hardware (for example a set of logic gates such as an FPGA or an ASIC). In the case where the invention is implemented on a reprogrammable calculation machine, the corresponding program (that is to say the sequence of instructions) can be stored in a removable storage medium (such as for example a diskette, a CD-ROM or a DVD-ROM) or not, this storage medium being readable partially or totally by a computer or a processor.

Claims (13)

REVENDICATIONS1. Method for assigning a mobile terminal to a voicemail server, characterized in that it comprises the following steps: - obtaining (21) geolocation information associated with the mobile terminal, indicating a geographical area where it is located most frequently the mobile terminal over a determined time period; - Assigning (22) the mobile terminal to a voicemail server selected from a plurality of voicemail servers based on the geolocation information associated with the mobile terminal. 2. Assignment method according to claim 1, characterized in that each of the voice mail servers is connected to a switching node, in that the geolocation information associated with the mobile terminal indicates the most frequent switching node for the mobile terminal, defined as the switching node most frequently traversed, during calls made during said time period determined by the mobile terminal, among the switching nodes to each of which is connected one of the voice mail servers, and in that that the assignment step is to assign the mobile terminal to the voice mail server connected to the most common switching node for the mobile terminal. 3. Assignment method according to any one of claims 1 and 2, characterized in that the obtaining step is reiterated (23) at least once and in that, if new geolocation information is obtained for the given mobile terminal, the assignment step is reiterated (25) and comprises a step of migrating the mobile terminal to another selected voice mail server according to the new geolocation information. 4. Assignment method according to any one of claims 2 and 3, characterized in that the switching nodes belong to a hierarchical network comprising a mesh of at least two central switching nodes, and in that each server of voicemail is connected to one of the central switching nodes. 5. Method for routing a voicemail call sent by a mobile terminal, characterized in that a first switching node implements the following steps: obtaining (34; 41) geolocation information associated with the mobile terminal, indicating a geographical zone where the mobile terminal is most frequently located over a determined temporal period; and - setting (35; 42) a circuit for routing the call to a voice mail server selected from a plurality of voicemail servers based on the location information associated with the mobile terminal. 6. Routing method according to claim 5, characterized in that the first switching node implements, when the mobile terminal is attached to a base station connected to the first switching node, a first routing policy comprising the 10 steps. following: - attempt to route (31) the call to a default voicemail server for the first switch node, and, - if a negative acknowledgment is received indicating that the mobile terminal has not previously assigned to the default voicemail server, performing the obtaining (34) and setting (35) steps. 7. Routing method according to claim 6, characterized in that the default voicemail server is associated with a predetermined geographical area such that, when a given mobile terminal is there most frequently over a given time period, the given mobile terminal is assigned to this default voicemail server. 20 A routing method according to claim 7, characterized in that the predetermined geographical area associated with the default voicemail server for the first switching node is a geographical area covered by a set of base stations which are operatively connected to a base station. switching node set, to which the first switching node belongs and comprising switching nodes 25 hierarchically dependent on the switching node to which the default voice mail server is connected. 9. Routing method according to claim 5, characterized in that the first switching node implements a second routing policy when the mobile terminal is attached to a base station connected to the first switching node, performing the 30 steps. of obtaining (41) and setting (42), without prior attempt to route the call to a default voicemail server for the first switching node. 10. Routing method according to any one of claims 5 to 9, characterized in that each of the voice mail servers is connected to a switching node, in that the geolocation information associated with the mobile terminal indicates the node of most frequent switching for the mobile terminal, defined as the most frequently traversed switching node, during calls made during said time period determined by the mobile terminal, among the switching nodes to each of which is connected one of the mail servers and in that the step of establishing a circuit is to establish a circuit to the voicemail server connected to the most common switching node for the mobile terminal. 11. Routing method according to any one of claims 6 to 8 and according to claim 9, characterized in that it comprises a step of dynamic change of the routing policy associated with the first switching node, with passage of the first to the second routing policy or vice versa, according to at least one predetermined criterion. 12. Device for assigning a mobile terminal to a voicemail server, characterized in that it comprises: - means (51 to 53) for obtaining a geolocation information associated with the mobile terminal, indicating a the geographical area where the mobile terminal is most frequently located over a determined temporal period; means (51 to 53) for allocating the mobile terminal to a voicemail server selected from a plurality of voicemail servers as a function of the geolocation information associated with the mobile terminal. 13. Device for routing a voicemail call transmitted by a mobile terminal, comprising: means (61 to 63) for obtaining geolocation information associated with said mobile terminal, indicating a geographical area where most frequently the mobile terminal over a determined time period; and circuit establishment means (61 to 63) for routing the call to a voicemail server selected from a plurality of voicemail servers based on the location information associated with the mobile terminal.